DE102006035168A1 - Lenses, method and apparatus for focusing solar light for solar photovoltaic generator using the concept of superposition - Google Patents

Abstract

The invention relates to a method for focusing the sunlight onto the focusing surface of the solar cells for generating electricity by means of the sunlight, as well as the Sonnenlichtsfokussierungslinsen and the focusing device for direct use for the method. The method according to the present invention for focusing the sunlight onto the focusing surface (11) of the solar cells (10) incorporated in the means for generating electricity by means of the sunlight is characterized in that the sunlight focus lenses (20), comprising a number of unitary lenses (21) whose areas correspond at least to the area of the condensing surface (11) above which solar cells are mounted parallel to the condensing surface (11); and that the sunlight incident on a number of unit lenses (21) is irradiated and focused superimposed on the focusing surface (11). As a result, this invention has the effect that the performance of the solar cells can be optimally maintained over the prior art.

Description

[TECHNICAL PART]

The The invention relates to a method for focusing the sunlight for the production of electricity by means of sunlight and lenses for use in the process.

[STATE OF THE ART]

in the general is understood by the term "production of electricity by means of of sunlight "the Technique, in which one uses the light energy of the sun by means of solar cells converted into electrical power. This means that the solar cells, made of PN junction semiconductors exist, generate free electrons when exposed to sunlight and electricity induce.

In the solar photovoltaic generator becomes a means of focusing such as using a lens or reflecting mirror, which focuses the sunlight and on the focusing surface of the Solar cells radiate, and the uniformity of Lichtintegationsgrades and the illuminance of the focusing means hangs directly related to the energy efficiency of the facilities generating electricity. Nevertheless, it was very much in the prior art focusing means difficult, the regularity the illuminance on the focusing surface the solar cells, since the focusing means according to the state the technique uses the sequential change of the focusing surface.

7 shows an embodiment of the Sonnenlichtsfokussierungslinsen according to the prior art; 7a is an open view and 7b is a side view. The illustrated sunlight focus lenses ( 30 ) are Fresnel lenses which are made flat-bed-like with respect to normal converging lenses and constructed such that a number of diffracted elevations ( 31 ) are configured on one side in the form of a circle and can focus the sunken light on the center.

Accordingly, the sunlight sunk on the lenses by the diffracted elevations ( 31 ) and onto the focusing surface ( 11 ) of the solar cells ( 10 However, such focusing lenses according to the prior art focus the sunlight by means of the successive change of the optical surface, and the farther the light focused on the focusing surface of the solar cells is away from the center, the more it falls Illuminance of the light, so that the uniformity of the illuminance can not be guaranteed.

Moreover it is disadvantageous in Sonnenlichtsfokussierungslinsen according to the state the technique that is an enlargement the sunlight focus lenses depending on the capacity of the generator is necessary, and the optical surface of Sonnenlichtsfokussierungslinsen must be designed sequentially, so that the production the Sonnenlichtsfokussierungslinsen is very expensive.

Meanwhile are the solar cells for use for the photovoltaic generator constructed such that a number of unit lenses in series or are connected in parallel, so that high voltages are generated, and the efficiency of the solar cells in dependence is determined by the unit lenses, which has a low amount of illumination to have.

Therefore, as explained above, when using the sunlight focusing lenses of the prior art, which are not even illuminance on the focussing surface, becomes the efficiency of the whole solar cells deteriorates because of the unitary lenses, which are located at the location where the illuminance is relative is low.

[TASK OF THE INVENTION]

task The present invention is the various above-mentioned Disadvantages eliminate by the method of focusing the sunlight for one solar photovoltaic generator in which sunlight over the Focused around the circumference of the focusing surface in uniform illuminance and the sunlight focusing lenses and focusing device for direct use for the method are provided.

[CONSTRUCTION OF THE INVENTION]

One Aspect of the method for focusing the sunlight according to the present invention Invention for solving such tasks is characterized in that that the sunlight focus lenses containing a number of unit lenses have, whose area the area the focusing surface corresponds, mounted above the solar cells parallel to the focusing surface are; and that that has fallen into a number of unit lenses Sunlight is superimposed on the focusing surface irradiated and focused becomes.

Furthermore, an aspect of the lenses for focusing the sunlight according to the present invention is characterized in that are flat-bed-mounted above the solar cells and have a number of unit lenses whose area corresponds at least to the area of the focusing surface; and that this number of unit lenses irradiate and focus the sunlight incident on each of the unit lenses superimposed on the focusing surface.

One aspect of the unitary lenses is characterized in that they include a non-diffracted light transmitting member and a number of Fresnel lenses in which a number of diffracted projections (Fig. 211 ) is configured on one side.

there the light-transmitting part is mounted vertically above the focusing surface, and the Fresnel lenses around the light transmitting part are arranged around.

Meanwhile The diffracted elevations of the Fresnel lenses are thus in constant intervals designed that the diffracted elevations perpendicular to the line starting from the Fresnel lenses to the center of the is aligned with light-transmitting part, and the farther the Fresnel lenses are removed from the light transmitting part, the more reduced the angle of inclination of the diffracted elevations.

One another aspect of the lenses for focusing the sunlight according to the present invention is characterized in that it is above the focusing surface of the Solar cells are mounted and have a number of unit lenses, their area at least the area the focusing surface corresponds; that the unit lenses on each of the unit lenses irradiate incident sunlight superimposed on the focusing surface and focus, and from a non-diffracted light-transmitting Part parallel to the vertical above the focusing surface attached, and a number of Fresnel lenses, the like down extended be that they both sides of the light-transmitting part respectively have the constant angle of inclination; and that the angle of inclination the Fresnel lenses in the range of 10 to 20 ° with respect to the light-transmitting Part is designed.

Moreover is one aspect of the device for focusing the sunlight according to the present invention, characterized in that it comprises solar cells, on one side of which the focusing surface is configured, the sunlight focus lenses, which are mounted above the solar cells parallel to the focusing surface and consist of a number of unit lenses whose area is at least the area the focusing surface corresponds, and a scaffolding, identifying the location of the sunlight focusing lenses, and that a number of unit lenses apply to each of the unit lenses Incident sunlight superimposed on the focusing surface irradiate and focus.

One Aspect of unit lenses is characterized by having a Variety of unit lenses from a non-diffracted light-transmitting Part and a number of Fresnel lenses in which a number of bent elevations are configured on one side, have.

there the light-transmitting part is mounted vertically above the focusing surface, and the Fresnel lenses are arranged so as to be appropriate the light-transmitting part can be designed comprehensively, or extended in both directions of the light transmitting part can.

Meanwhile The diffracted elevations of the Fresnel lenses are thus in constant intervals designed that the diffracted elevations perpendicular to the line starting from the Fresnel lenses to the center of the light-transmitting part is aligned, and the farther the Fresnel lenses are removed from the light transmitting part, the more reduced the angle of inclination of the diffracted elevations.

One another aspect of the device for focusing the sunlight according to The present invention is characterized in that it consists of Solar cells, on one side of the focusing surface designed is; the sunlight focus lens mounted above the focusing surface and have a plurality of unit lenses whose area is at least the area the focusing surface corresponds; and a scaffolding, which fixes the position of the sunlight focus lenses, that the unit lenses are incident on each of the unit lenses Irradiate and focus on sunlight superimposed on the focusing surface, and an un-diffracted light-transmitting part which is perpendicular above the focusing surface is mounted in parallel, and from a variety of Fresnel lenses, the so downhill extended be that they both sides of the light-transmitting part respectively have a constant angle of inclination exist; and that the angle of inclination the Fresnel lenses in the range of 10 to 20 ° with respect to the light-transmitting Part is designed.

The above aspects of the present invention will be explained in more detail by the embodiment with reference to the accompanying drawings. The invention will be described in detail so that a person skilled in the art can easily understand the present invention hen and can play.

[SHORT PRESENTATION OF THE PICTURES]

1 Fig. 11 is a view of the focusing device according to the first embodiment of the present invention;

2 is a bottom view of 1 ;

3 is a sectional view through the line AA of 2 ;

4 Fig. 12 is a diagram indicating the illuminance measured on the focusing surface of the solar cells;

5 Fig. 13 is a view showing the focusing device according to the second embodiment of the present invention;

6 Fig. 10 is a sectional view showing the focusing device according to the third embodiment of the present invention; and

7 shows an embodiment of the Sonnenlichtsfokussierungslinsen according to the prior art; 7a is an open view and 7b is a side view.

[TYPES]

1 is a view of the first embodiment of the present invention,

2 is a bottom view of 1 , and 3 is a sectional view through the line AA of 2 ,

The sunlight focusing lenses ( 20 ) according to the present invention, as shown, above a focusing surface ( 11 ) of the solar cells ( 10 ) are mounted in parallel and constructed such that they form a plurality of unit lenses ( 21 ) whose area at least the surface of the focusing surface ( 11 ) corresponds. In this embodiment, the sunlight focusing lenses ( 20 ) are constructed such that a total of 81 (9 × 9) unit lenses are connected to each other.

The unit lenses ( 21 ) are constructed in such a way that they reflect the respectively incident sunlight onto the focusing surface (FIG. 11 ) of the solar cells ( 10 ). Therefore, the degree of light integration thereby can be made essential over the prior art. be increased so that the sunlight, the area of which corresponds to the surface of the focusing surface, superimposed on the focusing surface by the number of unit lenses ( 21 ) can be irradiated. In addition, the focusing of the sunlight is not done in the manner of conventional focusing, but in the manner of superimposition, so that the uniform illuminance over the entire circumference of the focusing surface ( 11 ) is achieved.

In this embodiment, the unit lenses ( 21 ) from a non-diffracted light-transmitting part ( 210 ), which is located in the center region of the szenlichtsfokussierungslinsen ( 20 ) is arranged, and from a plurality of Fresnel lenses ( 211 ) which are arranged around the light transmitting part in a comprehensive manner and in which a number of diffracted elevations ( 211 ) are configured on one side.

Accordingly, in the light-transmitting part ( 210 Sunlight, as in 3 represented as it is transmitted and onto the focusing surface ( 11 ) of the solar cells ( 10 ) and into the Fresnel lenses ( 211 Sunlight is reflected by the diffracted elevations ( 211 ) diffracted by a certain angle and onto the focusing surface ( 11 ) irradiated.

Now the bent surveys ( 211 ) in the respective Fresnel lenses as in 2 configured at constant intervals such that the deflected elevations ( 211 ) perpendicular to the line starting from the Fresnel lenses ( 211 ) to the center of the light transmitting part ( 210 ), and the farther the Fresnel lenses (FIG. 211 ) of the light-transmitting part ( 210 ) are removed, the more the inclination angle (θ) of the diffracted elevations ( 211 ).

4 Fig. 10 is a graph indicating the illuminance measured on the focusing surface of the solar cells. The one graph (a) of the illustrated graphs indicates the illuminance measured in the transverse direction of the focusing surface while the other graph (b) indicates the illuminance measured in the diagonal direction of the focusing surface.

If one looks at the flat line of the diagram shown, it can be clearly seen that the sunlight when using the Sonnenlichtsfokussierungslinsen ( 20 ) according to the present invention over the entire circumference of the focusing surface ( 11 ) occurs in uniform illuminance. That is, by mounting the solar cells within the area of the flat line, uniformity of illuminance and also a high degree of light integration can be achieved.

5 Fig. 13 is a view indicating the second embodiment of the present invention. The sunlight focusing lenses ( 20 ) according to the second embodiment, as shown, are characterized in that the light-transmitting part ( 210 ) vertically above the focusing surface ( 11 ) and that the Fresnel lenses ( 211 ) are arranged such that they are in both directions of the light-transmitting part ( 210 ) can be extended.

That is, according to the Sonnenlichtsfokussierungslinsen 1 For example, the Fresnel lenses are made to comprehensively surround the light transmissive portion, so that the distances of the solar cells to each other can not be reduced by mounting a number of solar cells but the solar light focusing lenses according to the second embodiment are rod-shaped and the solar cells can be successively mounted that much more solar cells can be installed in the limited installation space.

6 Fig. 10 is a sectional view indicating the third embodiment of the present invention. In the case of sunlight focusing lenses ( 20 ) according to the third embodiment as shown, the inclination angle (α) of the Fresnel lenses (FIG. 211 ) in the above-mentioned second embodiment on both sides of the light-transmitting part ( 210 ) are inclined downwards at a constant angle in the range of 10 to 20 °.

If the Fresnel lenses themselves, as explained above, not flat, but be mounted at a certain angle, the collection area of the Sunlight expands and also reduces the scattering of light, so that the focusing efficiency is improved.

It as explained above, the structure and function of sunlight focus lenses according to of the present invention, and based on the explanation is the method of focusing the sunlight according to the present Invention explained as follows.

The method is characterized in that the sunlight focus lenses ( 20 ) above the solar cells ( 10 ) parallel to a focusing surface ( 11 ), which are a plurality of unit lenses ( 21 ) whose area at least the surface of the focusing surface ( 11 ) corresponds; and that on the respective unit lenses ( 21 ) incident sun light on the focusing surface ( 11 ) superimposed irradiated and focused.

The means, as explained above, in the process of the present invention, sunlight, their area the area the focusing surface corresponds to the focusing surface by the number of unit lenses irradiated by the sunken on the respective unit lenses Sunlight is broken and focused on the focusing surface Solar cells is irradiated.

Meanwhile, the focusing device employed directly in the focusing method of the present invention can be easily constructed with the focusing lenses of the present invention. In one embodiment, the focusing device is controlled by a solar cell ( 10 ), on one side of which the focusing surface ( 11 ) is configured; through sunlight focusing lenses ( 20 ) perpendicular to the focusing surface (FIG. 11 ) are flat-bed-mounted; and by a scaffold (not shown) which detects the position of the sunlight focus lenses ( 24 ) holds.

[EFFECT OF THE INVENTION]

As explained above, For example, this invention has the effect of focusing on the focusing surface Solar cells whose area the focusing surface corresponds to the light superimposed is focused, and the light over the entire area of the focusing surface is irradiated, so that the capacity the solar cell opposite the State of the art can be optimally maintained.

Meanwhile, although this invention with reference to the illustrated in the figures versions explained were, these are versions just to be considered as examples, and a skilled person may make different ones Modifications and other similar Remove applications. Accordingly, the actual must technical scope is determined only by the attached claims become.

Claims (13)

Sun light focusing lenses for generating electricity by means of sunlight using the concept of the overlay, characterized in that it (above the solar cells, 10 ) flat bed-like and a plurality of unit lenses ( 21 ) whose area at least the surface of the focusing surface ( 11 ) of the solar cells ( 10 ) corresponds; and that a plurality of unit lenses ( 21 ) incident on each of the unit lenses sun light on the focusing surface ( 11 ) superimposed irradiate and focus. Sonnenlichtsfokussierungslinsen to produce Supply of electricity by means of sunlight using the concept of superposition according to claim 1, characterized in that a plurality of unit lenses ( 21 ) a non-diffracted light-transmitting part ( 210 ) and a plurality of Fresnel lenses ( 211 ), in which a number of diffracted elevations ( 211 ) are configured on one side, have. Sunlight focusing lenses for generating electricity by means of sunlight using the concept of superposition according to claim 2, characterized in that the light-transmitting part ( 210 ) vertically above the focusing surface ( 11 ) and the Fresnel lenses ( 211 ) the light transmitting part ( 210 ) are arranged comprehensively. Sunlight focusing lenses for generating electricity by means of sunlight using the concept of superposition according to claim 2, characterized in that the light-transmitting part ( 210 ) vertically above the focusing surface ( 11 ) and the Fresnel lenses ( 211 ) are arranged such that they are in both directions of the light-transmitting part ( 210 ). Sunlight focusing lenses for generating electricity by means of sunlight using the concept of superposition according to claim 3 or 4, characterized in that the diffracted elevations ( 211 ) Fresnel lenses ( 211 ) are configured such that the bent surveys ( 211 ) perpendicular to the line starting from the Fresnel lenses ( 211 ) to the center of the light transmitting part ( 210 ), and the further the Fresnel lenses ( 211 ) of the light-transmitting part ( 210 ) are removed, the more the inclination angle (θ) of the diffracted elevations ( 211 ). Sonnenlichtsfokussierungslinsen for generating electricity by means of sunlight using the concept of superposition, characterized in that it above the focusing surface ( 11 ) of the solar cells ( 10 ) and a plurality of unit lenses ( 21 ) whose area at least the surface of the focusing surface ( 11 ) corresponds; that a plurality of unit lenses ( 21 ) incident on each of the unit lenses sun light on the focusing surface ( 11 superimposed irradiate and focus, and from a non-diffracted light-transmitting part ( 210 ), which is perpendicular above the focusing surface ( 11 ) is mounted in parallel, and from a plurality of Fresnel lenses ( 211 ) which are extended downwards so as to extend on both sides of the light transmitting part ( 210 ) each have the constant inclination angle (α); consist; and that the angle of inclination (α) of the Fresnel lenses ( 211 ) in the range of 10 to 20 ° with respect to the light transmitting part ( 210 ) is configured. Method for focusing the sunlight onto the focusing surface ( 11 ) of the solar cells ( 10 ) using the concept of superimposition, which are incorporated in the device for generating electricity by means of sunlight, characterized in that the Sonnenlichtsfokussierungslinsen ( 20 ), which have a large number of unit lenses ( 21 ) whose area corresponds to the area of the focusing surface ( 11 ), above the solar cells parallel to the focusing surface ( 11 ) are attached; and that on a variety of unit lenses ( 21 ) incident sun light on the focusing surface ( 11 ) superimposed irradiated and focused. Focusing device for generating electricity by means of sunlight using the concept of superposition, characterized in that it comprises solar cells ( 10 ), on one side of which the focusing surface ( 11 ) is configured; the sunlight focusing lenses ( 20 ) above the solar cells ( 10 ) parallel to the focusing surface ( 11 ) and a plurality of unit lenses ( 21 ) whose area at least the surface of the focusing surface ( 11 ) corresponds; and a framework that determines the location of the sunlight focusing lenses ( 20 ), identifies; and that a plurality of unit lenses ( 21 ) incident on each of the unit lenses sun light on the focusing surface ( 11 ) superimposed irradiate and focus. Focusing device for generating electricity by means of sunlight using the concept of superposition according to claim 8, characterized in that a plurality of unit lenses ( 21 ) a non-diffracted light-transmitting part ( 210 ) and a plurality of Fresnel lenses ( 211 ), in which a number of diffracted elevations ( 211 ) are configured on one side, have. Focusing device for generating electricity by means of the sunlight using the concept of superposition according to claim 9, characterized in that the light-transmitting part ( 210 ) vertically above the focusing surface ( 11 ) and the Fresnel lenses ( 211 ) the light transmitting part ( 210 ) are arranged comprehensively. Focusing device for generating electricity by means of the sun light using the concept of superimposition according to claim 9, characterized in that the light-transmitting part ( 210 ) vertically above the focusing surface ( 11 ) and the Fresnel lenses ( 211 ) are arranged such that they are in both directions of the light-transmitting part ( 210 ). Focusing device for generating electricity by means of sunlight using the concept of superposition according to claim 10 or 11, characterized in that the diffracted elevations ( 211 ) Fresnel lenses ( 211 ) are configured at constant intervals such that the bent elevations ( 211 ) perpendicular to the line starting from the Fresnel lenses ( 211 ) to the center of the light transmitting part ( 210 ), and the further the Fresnel lenses ( 211 ) of the light-transmitting part ( 210 ) are removed, the more the inclination angle (θ) of the diffracted elevations ( 211 ). Focusing device for generating electricity by means of sunlight using the concept of superposition, characterized in that it consists of solar cells ( 10 ), on one side of which the focusing surface ( 11 ) is configured; the sunlight focusing lenses ( 20 ) above the focusing surface ( 11 ) and a plurality of unit lenses ( 21 ) whose area at least the surface of the focusing surface ( 11 ) corresponds; and a framework that determines the location of the sunlight focusing lenses ( 20 ) holds that a plurality of unit lenses ( 21 ) incident on each of the unit lenses sun light on the focusing surface ( 11 superimposed irradiate and focus, and from a non-diffracted light-transmitting part ( 210 ), which is perpendicular above the focusing surface ( 11 ) is mounted in parallel, and from a plurality of Fresnel lenses ( 211 ) which are extended downwards so as to extend on both sides of the light transmitting part ( 210 ) each have the constant inclination angle (α) exist; and that the angle of inclination (α) of the Fresnel lenses ( 211 ) in the range of 10 to 20 ° with respect to the light transmitting part ( 210 ) is configured.